Linkage of the Nitrilase-Encoding Nit1C Gene Cluster to Cyanotrophy in Acinetobacter haemolyticus

Dale, Layla Momo

07 1900

The Nit1C cluster is a conserved gene cluster of seven genes that confers bacterial growth on cyanide as the sole nitrogen source. Bacteria with this ability are referred to as cyanotrophs. To date, the linkage between Nit1C and cyanotrophy has only been demonstrated for environmental isolates but the cluster also exists in certain medically related bacteria. In this study, a nosocomial isolate, Acinetobacter haemolyticus ATCC 19194, carrying Nit1C also displayed the ability to grow on cyanide. Growth on cyanide was accompanied by the induction of the cluster as was the mere exposure of cells to cyanide. Expression of the cluster was determined by measuring the activity of the nitrilase (NitC) coded for by the cluster and by transcriptional analysis (qRT-PCR). However, a disconnect between nitC message and NitC protein was observed depending on the phase of the growth cycle, the disconnect being related to proteolytic digestion of the NitC protein. Ironically, the cluster was also discovered to be upregulated in the absence of cyanide under nitrogen starvation conditions paralleling biofilm formation. The basis of the genetic linkage to cyanotrophy is not understood but taken together with results showing that nitrogen starvation and biofilm formation are also physiologically associated with Nit1C expression, points to a critical role for the cluster in stress-induced adaptation.

Nitrilase

Nit1C

cyanotrophy

Acinetobacter haemolyticus

cyanide

nitrogen starvation

Purification of Cyanide-Degrading Nitrilase from Pseudomonas Fluorescens NCIMB 11764.

Chou, Chia-Ni

12 1900

Cyanide is a well known toxicant that arises in the environment from both biological and industrial sources. Bacteria have evolved novel coping mechanisms for cyanide and function as principal agents in the biosphere for cyanide recycling. Some bacteria exhibit the unusual ability of growing on cyanide as the sole nitrogen source. One such organism is Pseudomonas fluorescens NCIMB 11764 (Pf11764) which employs a novel oxidative mechanism for detoxifying and assimilating cyanide. A unique complex of enzymes referred to as cyanide oxygenase (CNO) is responsible for this ability converting cyanide to ammonia which is then assimilated. Because one component of the four member CNO complex was previously shown to act on cyanide independent of the other members, its characterization was sought as a means of gaining a better understanding of the overall catalytic mechanism of the complex. Preliminary studies suggested that the enzyme belonged to a subset of nitrilase enzymes known as cyanide dihydratases (CynD), however, a cynD-like gene in Pf11764 could not be detected by PCR. Instead, a separate nitrilase (Nit) linked to cyanide metabolism was detected. The corresponding nit gene was shown to be one of a conserved set of nit genes traced to a unique cluster in bacteria known as Nit1C. To determine whether the previously described CynD enzyme was instead Nit, efforts were undertaken to isolate the enzyme. This was pursued by cloning and expressing the recombinant enzyme and by attempting to isolate the native enzyme. This thesis is concerned with the latter activity and describes the purification of a Nit-like cyanide-degrading nitrilase (NitCC) from Pf11764 to ~95% homogeneity. Purification was greatly facilitated by the discovery that fumaronitrile, as opposed to cyanide, was the preferred substrate for the enzyme (20 versus 1 U/mg protein, respectively). While cyanide was less effective as a substrate, the specificity for cyanide far outweighed that (10,000 fold) of the recombinant enzyme (NitPG) implying that the native NitCC protein purified in this work is different from that of the cloned recombinant. Further evidence of this was provided by molecular studies indicating that the two proteins differ in mass (34.5 and 38 kDa, respectively) and amino acid sequence. In summary, two different Nit enzymes are encoded by Pf11764. While the two share greater than 50% amino acid sequence identity, the results suggest that the native NitCC enzyme purified in this work functions better as a cyanide-degrading nitrilase and is one of four enzyme components comprising CNO required for Pf11764 cyanide assimilation.

cyanide dihydratase

Pseudomonas fluorescens 11764

cyanide-degrading nitrilase

fumaronitrile

cyanide oxygenase

Cyanides.

Pseudomonas fluorescens.

Bacterial growth.

Příprava a studium vlastností kyanidhydratasy z Aspergillus niger a nitrilasy z Arthroderma benhamiae / Preparation and characterization of cyanide hydratase from Aspergillus niger and nitrilase from Arthroderma benhamiae

Hradilová, Iveta

January 2014

Nitrilases are well known for their unique property to effectively convert nitriles into corresponding carboxylic acids and ammonia. They can also form amides as by-products. In contrast to nitrile hydratases they do not require cofactors or prosthetic groups. The research in this work is focused on nitrilase from filamentous fungus Arthroderma benhamiae and cyanide hydratase from Aspergillus niger K10. Genes of these enzymes were expressed using pET-30a(+) plasmid in the bacterium Escherichia coli strain BL21-Gold (DE3). The products obtained were purified by a series of ion exchange chromatography and gel filtration and subsequently characterized with respect to oligomeric state of the protein and its usability for protein crystallography. To obtain information regarding the structural arrangement of the individual proteins, electrophoretic separation in polyacrylamide gel, gel filtration, analytical ultracentrifugation, mass spectrometry, dynamic light scattering and drop coating deposition Raman spectroscopy were used. Keywords: nitrilase, cyanide hydratase, Aspergillus niger, Arthroderma benhamiae, liquid chromatography (In Czech)

Directed Evolution of Cyanide Degrading Enzymes

Abou Nader, Mary 1983-

14 March 2013

Cyanide is acutely toxic to the environment. However, this simple nitrile is used in several industrial applications especially the mining industry. Due to its high affinity to metals, cyanide has been used for years to extract gold and other precious metals from the ore. Cyanide nitrilases are considered for the detoxification of the industrial wastewaters contaminated with cyanide. Their application in cyanide remediation promises cheaper and safer processes compared to chemical detoxification. However, application of these enzymes in industry requires improving their characteristics. The goal of this dissertation is to better understand cyanide nitrilases, in particular the cyanide dihydratase from of Bacillus pumilus and Pseudomonas stutzeri and to improve their activity and stability. The lack of any high resolution structure of these enzymes calls for isolating or screening for mutants showing enhancement in enzyme properties. Described first is a simple and efficient method utilizing in vivo recombination to create recombinant libraries incorporating the products of PCR amplification. This method is useful for generating large pools of randomly mutagenized clones after error-prone PCR mutagenesis. Several parameters were investigated to optimize this technique; length of homology region, vector treatment, induction time and ratio of fragment to vector. Using error-prone PCR for random mutagenesis, several CynDpum mutants were isolated for higher catalysis at pH 7.7. Three point mutations, K93R, D172N and E327K increased the enzyme’s thermostability. The D172N mutation also increased the affinity of the enzyme for its substrate at pH 7.7 suggesting an effect on the active site. However, the A202T mutation located in the dimerization or the A surface rendered the enzyme inactive by destabilizing it. No significant effect on activity at alkaline pH was observed for any of the purified mutants. Lastly, an important region for CynDstut activity was identified in the C-terminus. This same region increased the stability of CynDpum compared to the wild-type enzyme. Also, CynDpum-stut hybrid was found to be highly more stable than CynDpum. This same hybrid exhibited 100% activity at pH9, a pH where the parent enzyme is inactive, and retained 40% of its activity at pH 9.5 making it a true pH tolerant mutant.

in vivo cloning

pH tolerant

cyanide bioremediation

cyanide hydratase

cyanide dihydratase

directed evolution

nitrilase

cyanide

Engineering pH tolerant mutants of a cyanide dihydratase of Bacillus pumilus C1 and identifying constraints on substrate specificity in nitrilases

Wang, Lan

15 May 2009

This study generated two cyanide dihydratase (CynD) mutants of Bacillus pumilus C1 with improved activity at higher pH by random mutagenesis. The purpose of this study was to create enzyme variants better suited to degrade cyanide under the harsh conditions of industrial applications. We employed error-prone PCR to construct a library of CynD mutants. A high throughput screening system was developed to screen the library for improved activity. Two mutants were identified that could degrade cyanide at pH10 whereas the wild-type enzyme was inactive at pH9 or higher. The mutants each had three amino acid substitutions compared to the wild-type enzyme. The mutants were also more stable than the wild-type enzyme at 42oC. E327G was identified as one of the key amino acids that are responsible for the improved activity. The goal of the second project was to convert substrate specificity of the Bacillus sp. OxB-1 nitrilase to that of a cyanidase by mutagenesis or construction of hybrid genes. The OxB-1 nitrilase of Bacillus sp. shows a high level of identity with the cyanide dihydratases from B. pumilus C1 and P. stutzeri AK61 but utilizes different substrate. This provides a valuable resource to study the substrate specificity determinants of cyanide degrading enzymes. One deletion mutant and four hybrid proteins were constructed based on the alignment information. The constructed proteins were all unable to degrade cyanide.

protein engineering

cyanide remediation

bioremediation

cyanide dihydratase

nitrilase

microbiology

gene cloning

genetic engineer

Modeling Substrate-Enzyme Interactions in Fungal Hydrolases / Modeling Substrate-Enzyme Interactions in Fungal Hydrolases

KULIK, Natallia

January 2011

Computational tools play an important role in the description of biological systems. Scientists describe and study structure, conformational changes and interactions between molecules in silico, often as a cheaper and faster alternative for biosynthesis. The simulated dynamic behavior in time of a molecular system is a straight forward source of information about substrate-enzyme interactions at the atomic level, and a powerful tool for the identification of molecular properties important in enzymatic reactions. Our study is focused on the computational investigation of structure and substrate specificity of hydrolases important in biotransformation. The computational work was performed in close collaboration with biochemists-experimentalists from Charles University and the Microbiological Institute of the Academy of Sciences of the Czech Republic. Hydrolases have great a potential in the chemoenzymatic synthesis of modified carbohydrates with regulated properties. Carbohydrates, as substrates of hydrolases, are important in normal functionality of many organisms. They have a dual role in immune response regulation: some carbohydrates (like GlcNAc and ManNAc) participate in activation and some (like GalNAc) in suppressing immunity; glycosidase deficiency is associated with a number of lysosomal disorders. We used homology modeling, computational docking and molecular dynamics simulation (MD) methods for the complex study of fungal hydrolases: alpha-galactosidase/alpha-N-acetylgalactosaminidase from Aspergillus niger; beta-N-acetylhexosaminidases (HEX) (from Aspergillus oryzae and Penicillium oxalicum); nitrilase from Aspergillus niger. Our structural study unambigously demonstrates that the enzyme encoded by genes variant A (aglA) from A. niger is able to accept alpha-N-acetylgalactosamine as its substrate and explains structural features responsible for its specificity. Homology models of HEXs from P. oxalicum and A. oryzae were built and compared. Homology models were used to study the role of protein glycosylation, disulfide bonds, dimer formation and interaction with natural and modified substrates. Model of nitrilase from Aspergillus niger helped to analyze multimer formation.

Modulação dos genes da nitrilase e do retrotransposon em cana-de-açúcar submetida a déficit hídrico

Barbosa, Anna Carolina Dal Ri [UNESP]

18 November 2008

Made available in DSpace on 2014-06-11T19:26:08Z (GMT). No. of bitstreams: 0 Previous issue date: 2008-11-18Bitstream added on 2014-06-13T20:14:43Z : No. of bitstreams: 1 barbosa_acdr_me_jabo_prot.pdf: 1040447 bytes, checksum: 48ed6a565f670b0e8919f670ff1f64ba (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / A seca é um dos principais fatores abióticos que afetam a produtividade das plantas. Para detectar os genes expressos sob condições de deficiência hídrica desenvolveu-se uma análise da expressão gênica das plantas de cana-de-açúcar de uma cultivar tolerante (cv. SP83-2847) e outra sensível (cv. SP90-1638) à seca, utilizando macroarranjos de DNA para monitorar a expressão gênica de 3.575 clones de folhas de cana-de-açúcar e, a partir dos resultados obtidos foram selecionados dois ESTs (SCJFLR2036B11 e SCBFLR1005E12) que se apresentaram como diferencialmente expressos nas duas cultivares. Os clones foram seqüenciados e identificados e correspondem ao gene que codifica para a Nitrilase e para elementos genéticos móveis (Retrotransposon). Os dados de expressão gênica foram validados por meio de RT-PCR semiquantitativo e Southem blotting e a seqüência de nucleotídeos obtida foi utilizada nas buscas em bancos de dados e na comparação de seqüência o que contribuiu para a atribuição de função biológica. O gene similar ao da Nitrilase apresentou-se induzido tanto na situação de deficiência hídrica no cultivar sensível (SP90-1638) como no cultivar tolerante (SP83-2847) nas plantas não expostas ao déficit hídrico. O gene que codifica um elemento genético móvel (Retrotransposon) apresentou-se induzido no cultivar tolerante na situação controle em detrimento da situação estressada e invariável para cultivá-Io sensível nas duas situações. / Drought is one of the main abiotic stresses which aftect plant productivity. To detect genes expressed under drought conditions, a gene expression study of sugarcane plants was performed, with drought tolerant (cv. SP83-2847) and sensitive (cv. SP90-1638) cultivars, using DNA macroarrays to monitor gene expression of 3.575 sugarcane leaf clones, and from the obtained results two ESTs (SCJFLR2036811 and SC8FLR1005E12) identified as difterentially expressed in both cultivars. were selected. The clones were sequenced and identified as the gene which codifies Nitrilase and mobile genetic elements (Retrotransposon). Gene expression data were confirmed by Semiquantitative RT-PCR and Southern blotting analysis, and the obtained nucleotide sequence used in database searches and in sequence comparisons, which contributed for the biological function attribution. The gene similar to Nitrilase appeared to be induced under water deficiency in the sensitive cultivar (SP90¬ 1638) as well as in the tolerant cultivar (SP83-2847) in plants not submitted to water deficit. The gene which codifies a mobile genetic element (Retrotransposon) appeared to be induced in the tolerant cultivar under the controlled condition in detriment of the stress, and unchanged for the sensitive cultivar under both conditions.

Cana-de-açúcar

Déficit hídrico

Expressão gênica

Nitrilase

Retrotransposon

water deficit

Gene expression

Studium funkce a molekulární architektury fungálních nitrilas využitelných v biokatalýze / Study of function and molecular architecture of fungal nitrilases applicable in biocatalysis

Veselá, Alicja Barbara

January 2015

Nitrilases are enzymes which catalyze the hydrolysis of a nitrile into the corresponding carboxylic acid and ammonia. These enzymes are potentially applicable in biocatalysis and bioremediation because of their advantages over the conventional (chemical) methods of nitrile hydrolysis (lower demand for energy, safety, simplicity, high yields, selectivity). In this work, genome mining was used to search for the sequences of hypothetical nitrilases from filamentous fungi. The amino acid sequences of previously characterized fungal nitrilases were used as the templates. Then the new synthetic genes together with other genes from our nitrilase library were expressed in E. coli and the substrate specificities of the enzymes thus produced were compared. Significant attention was focused on the relationships between the sequence of the enzyme and its substrate specificity. The arylacetonitrilases from Arthroderma benhamiae (NitAb) and Nectria haematococca (NitNh) were purified and characterized. Their substrate specificities, kinetic parameters, pH and temperature profiles and subunit and holoenzyme size were assessed. NitAb and NitNh together with other recombinant fungal nitrilases were employed in the hydrolysis of high concentrations of (R,S)-mandelonitrile in a batch or fed-batch mode. Nitrilase from...